JP2007045155A - Image forming device, method for detecting usage amount of ink ribbon, and recording medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To detect the usage amount of an ink ribbon by measuring the transfer speed of an initial position boundary line provided to the ink ribbon and sensing the width of the hue boundary line provided to the ink ribbon. <P>SOLUTION: The image forming device includes the ink ribbon, having an ink layer formed in its translucent sheet and equipped with the initial position boundary line indicating the initial position of the ink layer for printing on a unit print medium and with the hue boundary line dividing the hues of the ink layer, and the first usage amount detection part 410 and the second usage amount detection part 420 each measuring the moving speed of the initial position boundary line to detect the usage amount of the ink ribbon. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an image forming apparatus such as a printer, a facsimile machine, and a multi-function product (MFP), and more specifically, uses a thermal head for an ink ribbon in which an ink layer is formed on a light-transmitting sheet. The present invention relates to a thermal transfer type image forming apparatus that applies heat to transfer printing dye onto a sheet to print an image.

  In an image forming apparatus of a thermal transfer method such as a sublimation or melting method as shown in FIG. The ink ribbon is usually stored in a cassette and attached to the image forming apparatus. The ink ribbon is provided with a plurality of print areas that are divided so as to correspond to the size of the print medium 240. An ink layer having a predetermined hue is formed in the print area. The ink ribbon is stored in the ink ribbon cassette while being wound around the supply reel 200 and the take-up reel 210. The sensor 230 detects an ink layer and a boundary line formed on the ink ribbon. The thermal head (TPH) 220 generates heat and transfers the ink ribbon dye to a printing medium 240 such as paper.

  As shown in FIG. 1, the ink ribbon is provided with an initial position boundary line 100 that represents the initial position of the ink layer for printing the unit print medium and a hue boundary line 110 that divides the hue of the ink layer. The image forming apparatus includes a Y (yellow) hue ink layer 120, an M (magenta) hue ink layer 130, a C (cyan) hue ink layer 140, and an overcoating ink layer 150 provided on the ink ribbon. Heat is applied to each ink layer as described above, and sequentially printed on a print medium 160 as shown in FIG.

JP 2002-116580 A

  There are various types of ink ribbons depending on the size of the printing medium 240 such as A6 size and card size, the sensitivity of the dye (or pigment), and the presence or absence of an overcoating region. The user attaches an appropriate ink ribbon cassette to the image forming apparatus according to the application. Therefore, the ink ribbon stored in the ink ribbon cassette may be replaced with another ink ribbon cassette before it is used up. When the initial position boundary line 100 is counted and the amount of ink ribbon used is detected, there is a problem that when the ink ribbon cassette is replaced, the amount of ink ribbon used cannot be counted. If the ink ribbon cassette is provided with a memory and the amount of ink ribbon used is stored and detected, there is a problem that the cost increases.

  As described above, since the amount and remaining amount of the ink ribbon cannot be accurately detected by the conventional image forming apparatus, there is a problem in that it is inconvenient to use the image forming apparatus without knowing the replacement time of the ink ribbon.

  Therefore, the present invention has been made in view of the above problems, and an object of the present invention is to measure the moving speed of the initial position boundary line provided on the ink ribbon and to determine the hue provided on the ink ribbon. It is an object of the present invention to provide a new and improved ink ribbon usage detection apparatus and method for detecting the usage of an ink ribbon by detecting the width of a boundary line.

  In order to solve the above-described problem, according to an aspect of the present invention, an ink layer is formed on a translucent sheet, and an initial position boundary line indicating an initial position of the ink layer for printing a unit print medium, and an ink An image formation comprising: an ink ribbon having a hue boundary line that divides a hue of a layer; and a usage amount detection unit that detects a usage amount of the ink ribbon by measuring a moving speed of the initial position boundary line An apparatus is provided.

  The usage detector detects the moving speed of the initial position boundary line and outputs the result of the measured moving speed, and stores the ink ribbon usage corresponding to the moving speed of the initial position boundary line. A usage amount storage unit, and a usage amount determination unit that reads out the usage amount of the ink ribbon corresponding to the result output from the moving speed measurement unit from the usage amount storage unit.

  The initial position boundary line may include an opaque first boundary line and a second boundary line. The moving speed measuring unit senses the first boundary line and the second boundary line, outputs a detection result, and an initial position boundary line in response to the result output from the boundary line sensing unit. And a moving speed calculating unit that calculates the moving speed of.

  The ink ribbon may be provided with a different hue boundary line width every predetermined period. The usage amount detection unit measures the moving speed of the initial position boundary line and outputs a result of the measured moving speed, and is classified according to the period corresponding to the moving speed of the initial position boundary line. A range storage unit that stores the ink ribbon usage range, a range determination unit that reads the ink ribbon usage range corresponding to the result output from the moving speed measurement unit, and a hue boundary line width. And a usage amount calculation unit that senses and calculates the usage amount of the ink ribbon within the read usage range of the ink ribbon.

The usage amount calculation unit may calculate the usage amount of the ink ribbon using Formula 1.
(Where ATM is the amount of ink ribbon used, NUM _rng is the order in which the ink ribbon usage range is arranged, and T is the amount of ink ribbon used in one cycle) , NUM _wid is the order arranged by the period corresponding to the width of the sensed hue boundary lines)

  The initial position boundary line may include an opaque first boundary line and a second boundary line. The moving speed sensing unit senses the first boundary line and the second boundary line, outputs a sensed result, and an initial position boundary line in response to the result sensed by the boundary line sensing unit. And a travel time calculation unit that calculates the travel speed of.

  The ink ribbons may be provided with different hue boundary widths repeated at predetermined intervals. Then, it is determined whether or not two or more ink ribbon usage amounts read from the usage amount determination unit are read out, and the read value comparison unit that outputs the determined result corresponds to the moving speed of the initial position boundary line. In response to the results output from the read value comparison unit and the range storage unit that stores the usage range of the ink ribbon classified by period, the use of the ink ribbon corresponding to the result measured by the moving speed measurement unit A range determination unit that reads the amount range from the range storage unit, and a usage amount calculation unit that senses the width of the hue boundary line and calculates the usage amount of the ink ribbon within the read usage range of the ink ribbon. May be included.

  In order to solve the above problems, according to another aspect of the present invention, an ink layer is formed on a translucent sheet, and an initial position boundary line representing an initial position of the ink layer for printing a unit print medium. And a method for detecting the amount of ink ribbon used in an image forming apparatus that prints using an ink ribbon provided with a hue boundary line that divides the hue of the ink layer, and measuring the moving speed of the initial position boundary line There is provided a method for detecting the amount of ink ribbon used, the method including a moving speed measuring step and a detecting step of detecting the amount of ink ribbon used using the measured moving speed.

  In the detecting step, the usage amount of the ink ribbon corresponding to the measured moving speed may be read from the first recording medium in which the usage amount of the ink ribbon corresponding to the moving speed of the initial position boundary line is stored.

  The initial position boundary line may be provided with an opaque first boundary line and second boundary line. The moving speed measuring step includes a sensing step for sensing the first boundary line and the second boundary line, and a moving speed calculating step for calculating the moving speed of the initial position boundary line based on the result sensed in the sensing step. You may go out.

  The ink ribbons may be provided with different hue boundary widths repeated at predetermined intervals. In the detection step, the ink corresponding to the measured moving speed of the ink ribbon from the second recording medium in which the usage range of the ink ribbon classified according to the period corresponding to the moving speed of the initial position boundary line is stored. A reading step for reading out the ribbon usage amount range, and a usage amount calculating step for sensing the width of the hue boundary line and calculating the ink ribbon usage amount from the read out ink ribbon usage range. Also good.

In the usage amount calculating step, the usage amount of the ink ribbon may be calculated by using the following Equation 2.
(Where ATM is the amount of ink ribbon used, NUM _rng is the order in which the ink ribbon usage range is arranged, and T is the amount of ink ribbon used in one cycle, NUM _wid is the order arranged by the period corresponding to the width of the sensed hue boundary lines)

  The initial position boundary line may include an opaque first boundary line and a second boundary line. The moving speed measuring step includes a sensing step for sensing the first boundary line and the second boundary line, and a moving speed calculating step for calculating the moving speed of the initial position boundary line using the result sensed in the sensing step. , May be included.

  The ink ribbon may be provided with a different hue boundary line width every predetermined period. The method for detecting the amount of ink ribbon used is a determination step for determining whether or not two or more ink ribbon usage amounts read from the first recording medium are read, and the ink ribbon usage amount in the determination step. If it is determined that two or more are read out, the detected initial position boundary is detected from the second recording medium in which the usage amount range of the ink ribbon classified by the period corresponding to the moving speed of the initial position boundary line is stored. A reading step to read out the ink ribbon usage range corresponding to the moving speed of the line, and a usage amount to calculate the ink ribbon usage in the usage range of the read ink ribbon by sensing the width of the hue boundary line And a calculation step.

  In order to solve the above problems, according to another aspect of the present invention, there is provided a computer-readable recording medium on which a program for causing a computer to execute the above-described ink ribbon usage amount detection method is recorded. Is done.

  As described above, according to the present invention, the moving speed of the initial position boundary line provided on the ink ribbon is measured, and the amount of ink ribbon used is detected by sensing the width of the hue boundary line provided on the ink ribbon. To do.

  This makes it possible to measure the amount of ink ribbon used even when the ink ribbon is replaced, and the amount of ink ribbon used can be determined without an additional device such as a memory for storing the amount of ink ribbon used. However, the usage amount and remaining amount of the ink ribbon can be accurately detected, and the replacement timing of the ink ribbon can be predicted, so that convenience can be provided to the user.

  Exemplary embodiments of the present invention will be described below in detail with reference to the accompanying drawings. In addition, in this specification and drawing, about the component which has the substantially same function structure, duplication description is abbreviate | omitted by attaching | subjecting the same code | symbol.

  FIG. 4 is an explanatory diagram illustrating a block diagram of an ink ribbon usage detection device according to an embodiment of the present invention. The ink ribbon usage detection device includes a moving speed measurement unit 400 and a first usage detection. Unit 410 and a second usage amount detection unit 420. With reference to FIGS. 3 and 6 to 11D, driving of the ink ribbon usage detection device according to the present embodiment will be described.

  An ink ribbon (not shown) is accommodated in an ink ribbon cassette in a state of being wound around a supply reel and a take-up reel and mounted on an image forming apparatus so as to correspond to the size of a printing medium such as printing paper. A plurality of printing areas are provided that are partitioned and have an ink layer having a predetermined hue.

  FIG. 6 is an explanatory diagram illustrating an ink ribbon according to an embodiment of the present invention. The ink ribbon is formed by forming ink layers such as a Y hue ink layer 640, an M hue ink layer 650, a C hue ink layer 660, and an overcoating ink layer 670 on a translucent sheet, and an opaque initial position boundary. Line 600 and hue boundary lines 601-604, 611-613, 621-623, 631-633 are provided.

  The initial position boundary line 600 is provided with an opaque first boundary line 690 and second boundary line 691, and is used for printing a unit print medium (for example, a print medium divided into a predetermined unit such as one sheet). It represents the initial position of the ink layer.

  The hue boundary lines 601 to 604, 611 to 613, 621 to 623, and 631 to 633 are provided with one opaque line, and delimit the hue of the ink layer. In addition, the hue boundary lines 601 to 604, 611 to 613, 621 to 623, and 631 to 633 are provided so that the widths are repeated for each predetermined period. In FIG. 6, the predetermined period is set to four times the usage amount of the ink ribbon, and one of the four hue boundary lines 601, 611, 622, and 633 is used for printing the unit print medium. Each is selected and distinguished by having the width of the selected hue boundary line wider than the width of the unselected hue boundary line. The width of the second boundary line 601 positioned in front of the Y hue ink layer 640 is widened to indicate that the second boundary line 601 is first arranged in a predetermined cycle, and the hue boundary line positioned in front of the M hue ink layer 650 By increasing the width of 611, it is arranged second in a predetermined cycle, and by increasing the width of the hue boundary line 622 located in front of the ink layer 660 of C hue, the third is arranged in a predetermined cycle. This indicates that the hue boundary line 633 positioned in front of the ink layer of the overcoating 670 is widened and arranged fourth in a predetermined cycle. In this way, it is possible to distinguish the positions arranged in a predetermined cycle with respect to the usage amount of the ink ribbon by providing the hue boundary lines 601 to 604, 611 to 613, 621 to 623, and 631 to 633 to have different widths.

  FIG. 7 is an explanatory view showing an ink ribbon cassette according to an embodiment of the present invention.

  As shown in FIG. 7, the ink ribbon cassette stores the ink ribbon. The ink ribbon is wound around the supply reel 700 and the take-up reel 710. The unused ink ribbon is wound on the supply reel 700, and the used ink ribbon is wound on the take-up reel 710.

  The sensor 720 scans the ink ribbon with light and senses the first boundary line 690, the second boundary line 691, and the hue boundary line provided on the initial position boundary line 600 based on the amount of light reflected from the ink ribbon. FIG. 3 is a timing diagram for outputting a result sensed by the sensor 720. As shown in FIG. 3, the sensor 720 includes a Y hue ink layer 640, an M hue ink layer 650, a C hue ink layer 660, and an overcoating ink layer 670 provided on the ink ribbon corresponding to the transparent layer. Outputs a low level, and the first boundary line 690 and the second boundary line 691 and the hue boundary lines 602 to 604, 611 to 613, 621 to 623, and 631 provided on the initial position boundary line 600 corresponding to the opaque layer. At 633, a high level is output. However, the low level and high level output from the sensor 720 may change depending on the setting.

The boundary reference interval 680 refers to the interval between the tip of the first boundary line 690 and the tip of the second boundary line 691. The boundary reference interval 680 is expressed by Equation 1 below.
(Where L _td is the boundary reference interval 680, R _rr is the radius of the take-up reel 710, W is the rotational angular velocity of the take-up reel 710, and T _tb is the first boundary line. This is the travel time required until the second boundary line 691 is sensed after 690 is sensed)

If the above formula 1 is arranged and expressed with respect to T _tb, it is expressed by the following formula 2.

If Expression 2 is analyzed, L _td and W are fixed values, and only R _rr changes. If the ink ribbon is used and wound on the take-up reel 710, the radius of the take-up reel 710 increases, so that R _rr increases. As R _rr increases, T _tb decreases and the initial position boundary line 600 is increased. The movement speed increases gradually. Therefore, as the amount of ink ribbon used increases, the moving speed of the initial position boundary line 600 sequentially increases.

  FIG. 10 is a graph showing the relationship between the amount of ink ribbon used and the ink ribbon travel time according to an embodiment of the present invention. The horizontal axis represents the usage amount of the ink ribbon, and the vertical axis represents the moving time of the ink ribbon. Referring to the graph of FIG. 10, the ink ribbon moving time decreases as the ink ribbon usage increases, so the ink ribbon usage and the moving time have an inversely proportional relationship. Therefore, the moving speed of the initial position boundary line 600 gradually increases as the amount of ink ribbon used increases.

  11A to 11D are explanatory diagrams illustrating waveforms obtained by measuring the moving time of the ink ribbon with an oscilloscope. FIG. 11A shows a case where an ink ribbon prints one unit print medium, FIG. 11B shows a case where 11 unit print media are printed, and FIG. 11C shows a case where 21 unit print media are printed. FIG. 11D is a result of measuring the moving time of the ink ribbon corresponding to the case where 31 unit print media are printed with an oscilloscope. The waveforms in FIGS. 11A to 11D will be described. As shown in FIG. 10, as the amount of ink ribbon used increases, the movement time of the ink ribbon decreases and has an inversely proportional relationship, and the moving speed of the initial position boundary line 600 gradually increases. You can see that it gets faster.

  The movement speed measurement unit 400 measures the movement speed (or movement time) of the initial position boundary line 600 and outputs the measurement result to the first usage amount detection unit 410.

  The moving speed measuring unit 400 includes a boundary line sensing unit 403 and a moving speed calculating unit 406.

  The boundary line sensing unit 403 senses the first boundary line 690 and the second boundary line 691 by the sensor 720 of FIG. 7 and outputs the sensed result to the movement speed calculation unit 460.

  In response to the result sensed by the boundary line sensing unit 403, the movement speed calculation unit 406 measures the movement time Ttb required from sensing the first boundary line 690 to sensing the second boundary line 691 to determine the initial position. The moving speed of the boundary line 600 is calculated.

  The first usage amount detection unit 410 includes a usage amount determination unit 413 and a usage amount storage unit 416.

  The usage amount determination unit 413 searches the usage amount storage unit 416 to read out the usage amount of the ink ribbon corresponding to the movement speed of the initial position boundary line 600 calculated by the movement speed calculation unit 406.

  The usage amount storage unit 416 stores the usage amount of the ink ribbon corresponding to the moving speed of the initial position boundary line 600.

  FIG. 8 is an explanatory diagram illustrating data in the form of a lookup table stored in the usage amount storage unit 416 according to the embodiment of the present invention.

As shown in FIG. 8, instead of the movement speed of the initial position boundary line 600, the movement time T _tb required to move from the first boundary line 690 to the second boundary line 691 may be stored. The look-up table is data created by using the results that appear throughout the experiment.

  The second usage amount detection unit 420 includes a read value comparison unit 421, a range determination unit 422, a range storage unit 423, a width sensing unit 424, and a usage amount calculation unit 425.

  The read value comparison unit 421 determines whether or not two or more ink ribbon use amounts read from the use amount determination unit 413 are read, and outputs the determination result to the range determination unit 422. This is because the number of used ink ribbons due to the moving speed of the initial position boundary line 600 cannot be measured accurately due to measurement errors, such as the state of the ink ribbon or the measurement accuracy, and is calculated by the moving speed calculating unit 406. There may be a plurality of use amounts of the ink ribbon corresponding to the moving speed of the initial position boundary line 600. For example, referring to FIG. 8, when the movement time of the initial position boundary line 600 is measured as 106 ms, the ink ribbon usage corresponding to the movement time 106 ms is 12 times and 13 times, and the ink ribbon usage is However, the usage amount determination unit 413 reads two values and does not know whether the usage amount of the ink ribbon is 12 times or 13 times.

  If the read value comparison unit 421 determines that only one value of the ink ribbon usage amount has been read from the usage amount determination unit 413, the ink ribbon usage amount read from the usage amount determination unit 413 is used as the ink amount. Determine the amount of ribbon used and output.

  In response to the result output from the read value comparison unit 421, the range determination unit 422 calculates the movement speed calculation unit 406 if it is determined that two or more ink ribbon usages have been read. The range storage unit 423 reads the ink ribbon usage amount range corresponding to the moving speed of the initial position boundary line 600. For example, referring to FIG. 9, if the moving speed calculation unit 406 measures a moving time of 106 ms, it corresponds to a moving time Ttb corresponding to number 2 in FIG.

  The range storage unit 423 stores the ink ribbon usage range that is classified with a predetermined period corresponding to the moving speed of the initial position boundary line 600.

  FIG. 9 is an explanatory diagram showing data in the form of a lookup table stored in the range storage unit 423 according to the embodiment of the present invention. The look-up table shown in FIG. 9 is a table in which the used amount of ink ribbon stored in the used amount storage unit 416 shown in FIG.

  The width detection unit 424 detects the widths of the hue boundary lines 601 to 604, 611 to 613, 621 to 623, and 631 to 633, and outputs the detected results to the usage amount calculation unit 425.

The usage amount calculation unit 425 calculates the usage amount of the ink ribbon within the moving time range read from the range determination unit 422 in response to the result sensed by the width sensing unit 424. Here, the usage amount calculation unit 425 calculates the usage amount of the ink ribbon by using the following Equation 3.
(Where ATM is the amount of ink ribbon used, NUM _rng is the order in which the ink ribbon usage range is arranged, and T is the amount of ink ribbon used in one cycle, NUM _wid, corresponding to the width of the sensed hue boundary lines is the order arranged by the period.)

For example, when a moving time of 106 ms is measured by the moving speed calculation unit 406 and a hue boundary line 611 provided between the Y hue ink layer 640 and the M hue ink layer 650 is sensed by the width sensing unit 424. In the lookup table stored in the range storage unit 423 shown in FIG. 9, the movement time T _tb belongs to 106 ms to 121 ms, and therefore corresponds to the number 2. Therefore, NUM _rng is 2. As shown in FIG. 9, T is 5 because the range of the moving time is divided into five periods where the ink ribbon usage amount is one period. Since the hue boundary line 611 provided between the Y hue ink layer 640 and the M hue ink layer 650 is detected by the width sensing unit 424, it is arranged second in the cycle. _{The width} is 2. Therefore, ATM = 2 × 5 + 2 = 12, and the amount of ink ribbon used is 12 times.

  FIG. 5 is a flowchart illustrating a method for detecting the amount of ink ribbon used according to an embodiment of the present invention.

  First, the first boundary line 690 and the second boundary line 691 are sensed by the sensor 720 of FIG. 7 (step 500).

  After the first boundary line 690 is sensed using the result sensed in step 500, the time taken until the second boundary line 691 is sensed is measured to calculate the moving speed of the initial position boundary line 600 ( Step 510).

  The used amount of the ink ribbon corresponding to the moving speed of the initial position boundary line 600 calculated in step 510 is retrieved and read from the first recording medium (step 520). Here, the first recording medium stores the usage amount of the ink ribbon corresponding to the moving speed of the initial position boundary line 600.

  It is determined whether or not two or more ink ribbon usage amounts read in step 520 are read (step 530).

  If it is determined in step 530 that two or more are not read, the usage amount of the read ink ribbon is output (step 540).

  If it is determined in step 530 that two or more have been read, the ink ribbon usage range corresponding to the moving speed calculated in step 510 is read from the second recording medium (step 550). Here, the second recording medium stores the used amount range of the ink ribbon classified at a predetermined cycle corresponding to the moving speed of the initial position boundary line 600.

  After step 550, the widths of the hue boundary lines 602-604, 611-613, 621-623, 631-633 are sensed (step 560).

Using the hue boundary width sensed in step 560, the ink ribbon usage is calculated within the ink ribbon usage range read in step 550 (step 570). In step 570, the amount of ink ribbon used is calculated using Equation 4 below.
(Where ATM is the usage amount of the ink ribbon, NUM _rng is the order in which the usage range of the ink ribbon is arranged, and T is the usage amount of the ink ribbon included in one cycle, NUM _wid, corresponding to the width of the sensed hue boundary lines is the order arranged by the one cycle.)

  When the ink ribbon usage amount is calculated in step 570, the ink ribbon usage amount calculated in step 570 is output (step 580).

  The present embodiment can be embodied as a code that can be read by a computer (including any apparatus having an information processing function) on a computer-readable recording medium. Computer readable recording media include all types of recording devices that can store data that can be read by a computer system. Examples of a computer-readable recording device include a ROM (Read Only Memory), a RAM (Random Access Memory), a CD-ROM, a magnetic tape, a floppy (registered trademark) disk, and an optical data storage device.

  As mentioned above, although preferred embodiment of this invention was described referring an accompanying drawing, it cannot be overemphasized that this invention is not limited to the example which concerns. It will be apparent to those skilled in the art that various changes and modifications can be made within the scope of the claims, and these are naturally within the technical scope of the present invention. Understood.

6 is a diagram illustrating a conventional ink ribbon and a result output by the ink ribbon. It is a conceptual diagram of a conventional thermal transfer type image forming apparatus. FIG. 6 is a timing diagram for outputting a result sensed by a sensor according to an embodiment of the present invention. It is a block diagram which shows the usage-amount detection apparatus of the ink ribbon concerning one Embodiment of this invention. 3 is a flowchart illustrating a method for detecting the amount of ink ribbon used according to an embodiment of the present invention. It is explanatory drawing which shows the ink ribbon concerning one Embodiment of this invention. It is explanatory drawing which shows the ink ribbon cassette concerning one Embodiment of this invention. 6 is a diagram illustrating data in a lookup table format stored in a usage amount storage unit according to an exemplary embodiment of the present invention. 6 is a diagram illustrating data in a look-up table format stored in a range storage unit according to an exemplary embodiment of the present invention. It is a graph which shows the relationship between the usage-amount of an ink ribbon, and the movement time of an ink ribbon. It is explanatory drawing which shows the waveform which measured the movement time of the ink ribbon with the oscilloscope. It is explanatory drawing which shows the waveform which measured the movement time of the ink ribbon with the oscilloscope. It is explanatory drawing which shows the waveform which measured the movement time of the ink ribbon with the oscilloscope. It is explanatory drawing which shows the waveform which measured the movement time of the ink ribbon with the oscilloscope.

Explanation of symbols

400 Movement speed measurement unit 403 Boundary line sensing unit 406 Movement speed calculation unit 410 First usage amount detection unit 413 Usage amount determination unit 416 Usage amount storage unit 420 Second usage amount detection unit 421 Read value comparison unit 422 Range determination unit 423 Range Storage unit 424 Width detection unit 425 Usage amount calculation unit

Claims (23)

An ink ribbon having an ink layer formed on a translucent sheet and including an initial position boundary line representing an initial position of the ink layer for printing a unit print medium; and a hue boundary line that divides the hue of the ink layer;
A usage amount detector that detects a usage amount of the ink ribbon by measuring a moving speed of the initial position boundary line;
An image forming apparatus comprising: The usage detection unit
A moving speed measuring unit that measures a moving speed of the initial position boundary line and outputs a result of the measured moving speed;
A usage amount storage unit that stores the usage amount of the ink ribbon corresponding to the moving speed of the initial position boundary line;
A usage amount determination unit that reads out the usage amount of the ink ribbon corresponding to the result output from the moving speed measurement unit from the usage amount storage unit;
The image forming apparatus according to claim 1, further comprising: The initial position boundary line is
The image forming apparatus according to claim 1, comprising an opaque first boundary line and a second boundary line. The moving speed measuring unit is
A boundary line sensing unit that senses the first boundary line and the second boundary line and outputs a sensed result;
A moving speed calculating unit that calculates a moving speed of the initial position boundary line in response to a result output from the boundary line sensing unit;
The image forming apparatus according to claim 3, further comprising:   The image forming apparatus according to claim 1, wherein the ink ribbon is provided with a different hue boundary line width every predetermined period. The usage detection unit
A moving speed measuring unit that measures a moving speed of the initial position boundary line and outputs a result of the measured moving speed;
A range storage unit that stores a usage amount range of the ink ribbon classified in the cycle corresponding to the moving speed of the initial position boundary line;
A range determination unit that reads out the usage range of the ink ribbon corresponding to the result output from the moving speed measurement unit from the range storage unit;
A usage amount calculation unit that senses the width of the hue boundary line and calculates the usage amount of the ink ribbon within the read usage range of the ink ribbon;
The image forming apparatus according to claim 5, further comprising: The image forming apparatus according to claim 6, wherein the usage amount calculation unit calculates the usage amount of the ink ribbon by using Formula 1.
(Where ATM is the amount of ink ribbon used, NUM _rng is the order in which the ink ribbon usage ranges are arranged, and T is the amount of ink ribbon used in one cycle. _Yes , NUM width is the order arranged in the period corresponding to the detected width of the hue boundary)   The image forming apparatus according to claim 6, wherein the initial position boundary line includes an opaque first boundary line and a second boundary line. The moving speed sensing unit is
A boundary line sensing unit that senses the first boundary line and the second boundary line and outputs a sensed result;
A moving time calculating unit that calculates a moving speed of the initial position boundary line in response to a result sensed by the boundary line sensing unit;
The image forming apparatus according to claim 8, further comprising:   The image forming apparatus according to claim 2, wherein the ink ribbon is provided with a different width of the hue boundary line repeatedly at a predetermined period. A read value comparison unit that determines whether or not two or more ink ribbon use amounts read from the use amount determination unit are read; and outputs a result of the determination;
A range storage unit that stores a usage amount range of the ink ribbon classified in the cycle corresponding to the moving speed of the initial position boundary line;
A range determination unit that reads out from the range storage unit an ink ribbon usage amount corresponding to a result measured by the moving speed measurement unit in response to a result output from the read value comparison unit;
A usage amount calculation unit that senses the width of the hue boundary line and calculates the usage amount of the ink ribbon within the read usage range of the ink ribbon;
The image forming apparatus according to claim 10, further comprising: An ink ribbon in which an ink layer is formed on a translucent sheet, and an initial position boundary line that represents an initial position of the ink layer for printing a unit print medium, and a hue boundary line that divides the hue of the ink layer A method for detecting the amount of ink ribbon used in an image forming apparatus that performs printing using:
A moving speed measuring step for measuring a moving speed of the initial position boundary line;
A detecting step of detecting a use amount of the ink ribbon using the measured moving speed;
A method for detecting the amount of ink ribbon used. The detecting step includes
The usage amount of the ink ribbon corresponding to the measured moving speed is read from the first recording medium in which the usage amount of the ink ribbon corresponding to the moving speed of the initial position boundary line is stored. The method for detecting the amount of ink ribbon used according to 12.   The ink ribbon usage detection method according to claim 13, wherein the initial position boundary line includes an opaque first boundary line and second boundary line. The moving speed measuring step includes
A sensing step of sensing the first boundary line and the second boundary line;
A moving speed calculating step of calculating a moving speed of the initial position boundary line according to a result detected in the detecting step;
The method for detecting the amount of ink ribbon used according to claim 14, comprising:   The ink ribbon usage detection method according to claim 12, wherein the ink ribbon is provided with a different width of the hue boundary line repeatedly at a predetermined period. The detecting step includes
Use of the ink ribbon corresponding to the measured moving speed of the ink ribbon from the second recording medium in which the used amount range of the ink ribbon classified according to the period corresponding to the moving speed of the initial position boundary line is stored. A reading step for reading the quantity range;
A usage amount calculating step of sensing the width of the hue boundary line and calculating the usage amount of the ink ribbon from the read usage amount range of the ink ribbon;
The method for detecting an amount of ink ribbon used according to claim 16, comprising: The usage amount calculating step includes:
The method of detecting the amount of ink ribbon used according to claim 17, wherein the amount of ink ribbon used is calculated using the following formula 2.
(Where ATM is the usage amount of the ink ribbon, NUM _rng is the order in which the usage range of the ink ribbon is arranged, and T is the usage amount of the ink ribbon included in one cycle) , NUM _wid is the order arranged by the period corresponding to the width of the sensed hue boundary lines)   The method of claim 17, wherein the initial position boundary line includes an opaque first boundary line and a second boundary line. The moving speed measuring step includes
A sensing step of sensing the first boundary line and the second boundary line;
A moving speed calculating step of calculating a moving speed of the initial position boundary line using a result detected in the detecting step;
The method for detecting the amount of ink ribbon used according to claim 19, comprising:   The ink ribbon usage detection method according to claim 13, wherein the ink ribbon is provided with different hue boundary widths repeated at predetermined intervals. A determination step of determining whether or not two or more usage amounts of the ink ribbon read from the first recording medium are read;
If it is determined in the determining step that two or more ink ribbon usage amounts are read, the ink ribbon usage range classified by the period corresponding to the moving speed of the initial position boundary line is stored. A reading step of reading out a usage amount range of the ink ribbon corresponding to the sensed moving speed of the initial position boundary line from the second recording medium;
A usage amount calculating step of sensing the width of the hue boundary line and calculating the usage amount of the ink ribbon within the read usage range of the ink ribbon;
The method for detecting the amount of ink ribbon used according to claim 21, further comprising: 23. A computer-readable recording medium on which a program for causing a computer to execute the ink ribbon usage amount detection method according to claim 12 is recorded.